System and method for automatic detection of webpage zones of interest

ABSTRACT

A system and method for detecting webpage zones of interest. A method includes receiving at least one webpage analysis request, wherein the received at least one webpage analysis request includes at least one webpage in a website; identifying, in the at least one webpage, at least one zone, wherein the at least one zone is a content element of a webpage; classifying the at least one zone into a category of interest, wherein the classification is based on a trained machine learning model configured to classify DOM elements of the least one webpage, and wherein a category of interest is a category determined based on a functionality of the website; and storing the classification by indicating the category of interest for each zone.

CLAIM OF PRIORITY

This application is a Continuation of U.S. application Ser. No.16/915,190, filed Jun. 29, 2020, which is hereby incorporated byreference in its entirety.

TECHNICAL FIELD

The present disclosure relates generally to analysis of webpage elementsand, specifically, to systems and methods for automatic detection ofzones of interest within webpages.

BACKGROUND

As web access and use becomes increasingly prevalent, the volume ofweb-based content in commerce, education, communication, andentertainment, among other fields, continues to increase. Further, theincreasing prevalence of web-based content includes both expanding basesof web content and increasing complexity of the same. A given website orpage may include dozens or hundreds of unique zones or elements. Whilewebpage content, including the relevant zones and elements, may bedesigned to improve a user's experience, the variety of ways in whichthe various zones or elements can be arranged reduces the ability of asite administrator to quickly understand the content and arrangement ofa page, particularly using automated methods, allowing the administratorto execute various improvements of a given page or site.

The difficulties of automatically analyzing webpage zones or elementspresents a significant hurdle to subsequent applications ofweb-optimization technologies. Certain solutions in webpage zone orelement analysis include parsing solutions. However, such solutions maynot indicate whether a given zone is of interest. Classificationapplications, in certain solutions used for detection of zones ofinterest, may be limited to detection only of webpage layout zone types,such as headers, footers, navigation elements, logos, as well as otherzone types, and may lack the capacity to automatically detect zones ofinterest which are critical to a positive user experience.

Further, classification solutions may lack performance optimizationsnecessary to provide the user experience expected, and may be limited toisolated zone classification and detection, detecting and classifyingzones based only on code-level zone descriptions, such as an HTML headertag, rather than detection and classification based on page structureinformation. In addition, a classification solution may be limited bythe nature of the solutions' independent binary classification models,where the number of trained models generated to detect zones is relatedto the number of types of zones to be detected, such as may be the casefor models trained to identify a zone as a header or not a header, andthe like, compounding the noted lack of performance optimizations.

It would therefore be advantageous to provide a solution that wouldovercome the challenges noted above.

SUMMARY

A summary of several example embodiments of the disclosure follows. Thissummary is provided for the convenience of the reader to provide a basicunderstanding of such embodiments and does not wholly define the breadthof the disclosure. This summary is not an extensive overview of allcontemplated embodiments and is intended to neither identify key orcritical elements of all embodiments nor to delineate the scope of anyor all aspects. Its sole purpose is to present some concepts of one ormore embodiments in a simplified form as a prelude to the more detaileddescription that is presented later. For convenience, the terms “someembodiments” or “certain embodiments” may be used herein to refer to asingle embodiment or multiple embodiments of the disclosure.

Certain embodiments disclosed herein include a method for detectingwebpage zones of interest. The method comprises: receiving at least onewebpage analysis request, wherein the received at least one webpageanalysis request includes at least one webpage in a website;identifying, in the at least one webpage, at least one zone, wherein theat least one zone is a content element of a webpage; classifying the atleast one zone into a category of interest, wherein the classificationis based on a trained machine learning model configured to classify DOMelements of the least one webpage, and wherein a category of interest isa category determined based on a functionality of the website; andstoring the classification by indicating the category of interest foreach zone.

Further, certain embodiments disclosed herein also include anon-transitory computer readable medium having stored thereoninstructions for causing a processing circuitry to execute a process.The process comprises: receiving at least one webpage analysis request,wherein the received at least one webpage analysis request includes atleast one webpage in a website; identifying, in the at least onewebpage, at least one zone, wherein the at least one zone is a contentelement of a webpage; classifying the at least one zone into a categoryof interest, wherein the classification is based on a trained machinelearning model configured to classify DOM elements of the least onewebpage, and wherein a category of interest is a category determinedbased on a functionality of the website; and storing the classificationby indicating the category of interest for each zone.

In addition, certain embodiments disclosed herein include a system fordetecting webpage zones of interest. The system comprises: a processingcircuitry; and a memory, the memory containing instructions that, whenexecuted by the processing circuitry, configure the system to: receiveat least one webpage analysis request, wherein the received at least onewebpage analysis request includes at least one webpage in a website;identify, in the at least one webpage, at least one zone, wherein the atleast one zone is a content element of a webpage; classify the at leastone zone into a category of interest, wherein the classification isbased on a trained machine learning model configured to classify DOMelements of the least one webpage, and wherein a category of interest isa category determined based on a functionality of the website; and storethe classification by indicating the category of interest for each zone.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing and other objects, features, and advantages of thedisclosed embodiments will be apparent from the following detaileddescription taken in conjunction with the accompanying drawings.

FIG. 1 is an example network diagram depicting a network systemdisclosing the embodiments for automatic detection of webpage zones ofinterest.

FIG. 2 is an example flowchart describing a method for automaticdetection of webpage zones of interest, according to an embodiment.

FIG. 3 is an example flowchart describing a method for classifyingwebpage zones and elements using a trained model, according to anembodiment.

FIG. 4 is an example flowchart describing a method for training a systemfor automatic detection of webpage zones of interest, according to anembodiment.

FIG. 5A is a diagram depicting an unlabeled document object model (DOM)tree, according to an embodiment.

FIG. 5B is a diagram depicting a labeled document object model (DOM)tree, according to an embodiment.

FIG. 6 is a page and zone categorization table, according to anembodiment.

FIG. 7A is an illustration depicting a webpage prior to zoneidentification, according to an embodiment.

FIG. 7B is an illustration depicting a webpage following zoneidentification, according to an embodiment.

FIG. 7C is an illustration depicting a webpage following zoneidentification and including a zone identification confidence score,according to an embodiment.

FIG. 8 is a schematic diagram of an analytic engine, according to anembodiment.

DETAILED DESCRIPTION

It is important to note that the embodiments disclosed herein are onlyexamples of the many advantageous uses of the innovative teachingsherein. In general, statements made in the specification of the presentapplication do not necessarily limit any of the various claimedembodiments. Moreover, some statements may apply to some inventivefeatures but not to others. In general, unless otherwise indicated,singular elements may be in plural and vice versa with no loss ofgenerality. In the drawings, like numerals refer to like parts throughseveral views.

The various disclosed embodiments include a method and system forautomatic detection of webpage zones of interest. As webpages mayinclude a variety of content zones and elements which may be relevant touser experience, classification of such zones and elements may providefor application of additional solutions to optimize various aspects ofwebpage user experiences. The disclosed system and method addresses theneed for such classifications, providing an application of machinelearning techniques to the automatic detection and classification ofwebpage content zones and elements.

FIG. 1 is an example network diagram depicting a network system 100disclosing the embodiments for automatic detection of webpage zones ofinterest. The system 100 includes one or more user devices, 120-1through 120-N (hereinafter, “user device” 120 or “user devices” 120), ananalytic engine 130, one or more web servers, 140-1 through 140-N(hereinafter “web server” 140 or “web servers” 140), and a database 150.Further, in the system, the various components listed are interconnectedvia a network 110.

The network 110 provides interconnectivity between the variouscomponents of the system. The network 110 may be, but is not limited to,a wireless, cellular or wired network, a local area network (LAN), awide area network (WAN), a metro area network (MAN), the Internet, theworldwide web (WWW), similar networks, and any combination thereof. Thenetwork may be a full-physical network, including exclusively physicalhardware, a fully-virtual network, including only simulated or otherwisevirtualized components, or a hybrid physical-virtual network, includingboth physical and virtualized components. Further, the network 110 maybe configured to encrypt data, both at rest and in motion, and totransmit encrypted, unencrypted, or partially-encrypted data. Thenetwork 110 may be configured to connect to the various components ofthe system 100 via wireless means such as, as examples and withoutlimitation, Bluetooth™, long-term evolution (LTE), Wi-Fi, other, like,wireless means, and any combination thereof, or via wired means such as,as examples and without limitation, ethernet, universal serial bus(USB), other, like, wired means, and any combination thereof. Further,the network 110 may be configured to connect with the various componentsof the system 100 via any combination of wired and wireless means.

The user devices 120 may be devices allowing a user to interact with thesystem 100 for purposes including, as examples and without limitation,providing webpage analysis requests to the system 100 for detection andclassification of content elements and zones, receiving classificationreports from the system 100, configuring system 100 parameters, other,like, purposes, and any combination thereof. The user devices 120 may bedevices configured to allow a user to receive information throughfeatures such as, as examples and without limitation, video screens,audio speakers, text printers, and other, like, output features. Theuser devices 120 may be further configured to allow a user to inputinformation. Further, the user devices 120 may be configured to allowusers to simultaneously receive and input information, includingsimultaneously. The user devices 120 may include one or more componentsconfigured to provide network connectivity, allowing the user devices120 to connect with the network 110, including by the means describedwith respect to the network 110, above. Examples of user devices 120 maybe smartphones, personal computers, business systems, dedicated kiosks,tablet computers, and other, like, devices.

The analytic engine 130, depicted in detail with respect to FIG. 8 ,below, is a system configured to execute instructions, organizeinformation, and otherwise process data. The analytic engine 130 may beconfigured to execute the methods described hereinbelow, other, like,methods, and any combination thereof. As described with respect to FIG.8 , below, the analytic engine 130 may include various processing,memory, networking, and other components allowing the analytic engine130 to execute instructions and provide data processing. The analyticengine 130 may be implemented as physical hardware, as softwarevirtualizing physical hardware, or as a combination of physical andvirtualized components. The analytic engine 130 may be connected to thenetwork 110 via those means described with respect to the network 110,above.

According to the disclosed embodiments, the analytic engine 130 isconfigured to identify zones of interest within websites and webpages. Azone is an area in a webpage including one or more objects. Such zonesmay be features of common web technologies such as Hypertext MarkupLanguage (HTML) and Cascading Style Sheets (CSS), and may provide forrich user interactions with a website or page. As an example, an onlineretailer's page may include zones or elements allowing users to searchfor products, to add products to a digital shopping cart, to contact aretailer's support specialist via a chat popup, and the like. A zone ofinterest may be a webpage zone or element directed to a particularfunction or aspect of the user experience, where various zones ofinterest may be defined in various contexts, including by manualspecification of specific zones of interest and automatic identificationof zones of interest based on factors including, without limitation,collected site usage data, intended site functions, such as social,shopping, and the like, other, like, factors, and any combinationthereof. An example of a zone of interest may be a table of productprices on a shopping website, distinguished from other zones in the samewebsite by a particular specification describing product-related zonesas zones of interest and other zones as not of interest.

As will be discussed in detail below, the analytic engine 130 isconfigured to identify webpage zones of interest by receiving a webpageanalysis request, identifying webpage content elements and zones, andclassifying webpage content elements and zones. The classification maybe performed using one or more machine learning techniques.

The web servers 140 may be one or more sources of data other than theinputs received from the user devices 120. The web servers 140 mayinclude data relating to execution of instructions, data relating to thetraining of models, as described hereinbelow, other, like, data, and anycombination thereof. Data from the web servers 140 may be stored in thedatabase 150 and may be processed by the analytic engine 130. Webservers 140 may be local sources, remote sources, or any combinationthereof. Examples of web servers 140 include, without limitation,repositories of webpage information, repositories of webpage element orzone classifications, “live” webpages, other, like, sources, and anycombination thereof. Web servers 140 may be connected with the network110 via the means described hereinabove. In some configurations, the websources 140 may include one or more data sources sorting contentelements that can be utilized to train a model, as describedhereinbelow.

Further, where detection of webpage zones of interest is achieved viamethods including the receipt of a webpage analysis request, such asthose described hereinbelow, the webpage analysis request may include aspecification of a specific webpage, with the contents of the specificwebpage being drawn, by the system executing such a method, from the webservers 140. In addition, where detection of webpage zones of interestincludes the training of one or more models or algorithms based on apredefined dataset, the dataset including various webpages, the webpagesincluded in the training dataset, and the contents thereof, may bedrawn, by the system training the models or algorithms, from the webservers 140.

The database 150 is a data store configured to archive data permanentlyor semi-permanently. The database 150 may be configured to storeinformation received from one or more web servers 140, user devices 120,and other, like, components, as well as to store data relevant to theoperation of the analytic engine 130 and any outputs therefrom. Thedatabase 150 may be a local system, a remote system, or a hybridremote-local system. Further, the database 150 may be configured as afull-physical system, including exclusively physical components, as avirtualized system, including only virtualized components, or as ahybrid physical-virtual system.

The database 150 may be configured to store or otherwise archive datarelating to detection, identification, and classification of webpagezones and elements of interest including, without limitation, webpages,HTML code, Document Object Model (DOM) trees, training datasets, userinputs, other, like, data, and any combination thereof. Further, thedatabase 150 may be configured to transfer, to and from the analyticengine 130, data necessary for the execution of the methods describedhereinbelow, and may store or otherwise archive analytic engine 130inputs, analytic engine 130 outputs, or both.

FIG. 2 is an example flowchart 200 describing a method for automaticdetection of webpage zones of interest, according to an embodiment. Themethod depicted in the flowchart 200 may be applicable to the detectionof one or more predefined zone or element types within a webpage. It maybe noted that, while the flowchart 200 describes a method relevant to asingle webpage, the same or similar methods may be applicable tomultiple webpages, including simultaneous execution for multiplewebpages, without loss of generality or departure from the scope of thedisclosure.

At S210, a webpage analysis request is received. A webpage analysisrequest may include a specific webpage or set of webpages in which auser wishes to detect zones of interest. A webpage analysis request maybe received from a user device, such as the user device, 120, of FIG. 1, above. A webpage analysis request may be generated by user interactionwith an online analysis portal, a browser extension connected to a webbrowser installed in a user device, such as the user device 120, of FIG.1 , above, an application installed on such a user device, other, like,interactions, and any combination thereof. The webpage analysis requestmay be sent, via a network, such as the network, 110, of FIG. 1 , above,to an analytic engine, such as the analytic engine, 130, of FIG. 1 ,above. Further, one or more webpage analysis requests may be stored in adatabase, such as the database, 150, of FIG. 1 , above. Webpage analysisrequests stored in a database may be processed, either simultaneously orin any order, including by order of receipt, by an analytic engine, suchas that described above, according to the method described hereinbelow,as well as according to other, like, methods.

In an embodiment, a webpage analysis request, as received at S210, mayinclude a specification of a page category. A specification of a pagecategory may be included in the request generated as described above,and may specify one or more categories, such as those included in theexample categorization table of FIG. 6 , below, as well as other, like,categories. A specification of a page category may provide forstreamlined zone and element detection and identification by specifyingthat the received webpage analysis request is relevant only to zones orelements falling within the sub-categories included in the request'scategory specification.

At S220, content elements and zones are identified. Content elements andzones are identified based on the contents of the code defining thecontents of the webpage specified in the webpage analysis requestreceived at S210. The code defining the contents of the webpage may beHypertext Markup Language (HTML) or another, similar webpage formattingor markup language. The code defining the elements of the webpage mayinclude element or zone labels delineating the various elements or zonesof the webpage. As an example, the HTML code for a given webpage mayinclude code contained within a “header” section, defined by a specificheader tag. In the same example, the header section may be defined by afirst tag and a second tag marking the beginning and end of the headersection. Further, the contents of a given section, marked by tags, asdescribed above, may be further sub-sectioned such that a first sectionmay contain first, second, and third subsections, each containingvarious zones.

Content elements and zones may be identified by analysis of theunderlying HTML code of a webpage and the corresponding document objectmodel (DOM) tree describing the given webpage. As described in detailwith respect to FIG. 5A, below, a DOM tree may provide a hierarchicaldescription of the elements of a webpage and the various sections andsubsections of the webpage to which those elements belong. Analysis of awebpage's DOM tree to identify content zones and elements may includethe detection of one or more content elements or zones, represented in aDOM tree as nodes. Content elements or zones may be detected by theapplication of natural language processing (NLP) techniques, and other,like, techniques, to the HTML code underlying the webpage. Inapplication of NLP techniques, and other, like, techniques, the text ofthe HTML code may be analyzed to detect characters, strings, and othertext features corresponding to webpage content elements or zones. As anexample, application of NLP techniques to the identification of contentelements or zones within the HTML code underlying a webpage may includethe detection of “<header>” and “</header>” strings, representing thebeginning and end, respectively, of a header section of a webpage.

At S230, content elements and zones are classified. Content elements andzones may be classified at S230 based on the content elements and zonesidentified at S220 and the application of one or more machine learningor similar models, the training of which is described with respect toFIG. 4 , below. Classification at S230 may include the classification ofcontent elements or zones into various content categories andsub-categories, such as those included in the categorization table, 600,of FIG. 6 , below, including through the use of a trained model, asdescribed with respect to FIG. 3 , below. The classification of contentelements and zones at S230 may include a selective classificationconfiguration. In a selective classification configuration, only contentzones or elements matching specific categories or subcategories areclassified according to their respective categories or sub-categories,while content zones or elements not matching the same specificcategories or subcategories are be classified as “other,” providing forreduced processing load during execution and improved classificationspeed and efficiency. Classification of zones or elements according topre-defined categories or subcategories may be achieved through theapplication of one or more categorization tables, such as that describedwith respect to FIG. 6 , below. As an example, a selectiveclassification configuration may include the classification of zones as“menu,” “account,” “cart,” and “other,” where the webpage analysisrequest received at S210 includes a specification indicating that theuser or administrator wishes to detect only “menu,” “cart,” and“account” zones, or where the same categories make up the full extent ofall applicable pre-defined categories. The classification of contentelements and zones at S230 may include the labeling of webpage contentelements and zones in the corresponding DOM trees, reflecting theunderlying HTML code, as is described with respect to FIG. 5B, below.

At S240, the results of the zone classification are returned. Theresults of the classification returned at S240 may be returned visually,as shaded highlights and zone labels appearing over relevant contentelements or zones, as depicted with respect to FIG. 7B, below. Further,returning the results of the classification at S240 may include thegeneration and return of one or more zone identification confidencescores, as depicted with respect to FIG. 7C, below. Zone identificationconfidence scores reflect the degree of certainty regarding theclassification applied to a particular content zone or element. Zoneidentification confidence scores may be presented as percentages,reflecting the likelihood that the given content zone or element matchesthe corresponding classification. Zone identification confidence scoresmay be generated based on the HTML code represented by the given contentzone or element, the rules developed during training of the machinelearning model, as described with respect to FIG. 4 , below, other,like, factors, and any combination thereof.

In an embodiment, returning classification results at S240 may includereturning zone shading indicators, zone labels, and zone identificationconfidence scores for some, all, or none of the zones or elementsincluded in a given webpage, including return of shading indicators,labels, and confidence scores for specific zones or elements, as well ascategories and subcategories thereof, as specified by an operator,administrator, or other user. Further, returning classification resultsat S240 may include returning classification results in formats otherthan those described, including, without limitation, textualdescriptions, labeled HTML code sets, labeled DOM trees, other, like,formats, and any combination thereof. Classification results returned atS240 may be displayed visually for user interpretation, saved to astorage medium, or otherwise retained for subsequent evaluation.

FIG. 3 is an example flowchart 300 describing a method for classifyingwebpage zones and elements using a trained model, according to anembodiment.

At S310, a webpage's document object model (DOM) is extracted. Thewebpage's document object model (DOM) describes the content andstructure of the HTML code underlying the webpage. The DOM may berepresented visually as a “node-and-link” tree graph, such as that shownwith respect to FIG. 5A, below. The webpage's DOM may be extracted byanalysis of the webpage's underlying HTML code using methods including,without limitation, application of various application programminginterfaces (APIs) directed to the generation of DOMs based on HTML, aswell as other, like, methods. Where APIs directed to the generation ofDOMs based on HTML are applied to the extraction of a webpage's DOM, theAPIs applied may be included in a web browser, may be integrated inanother application, or may be configured to operate as standaloneinterfaces for DOM extraction.

At S320, content elements and zones are identified in the extracted DOMand in the webpage's HTML code. Content elements and zones may beidentified in the extracted DOM by analysis of the DOM's contents andstructure. Content elements and zones may be identified in the DOM byassessment of the “nodes” included in the DOM, describing the elementsand zones included in the webpage, and by assessment of the “links”between the nodes, describing the hierarchy or structure of the webpagerepresented by the DOM.

Content elements and zones may be identified in the webpage's HTML codeby application of techniques including, without limitation, naturallanguage processing (NLP), and the like. In the application of NLPtechniques to the identification of content elements and zones in thewebpage's HTML code, the HTML code underlying the website may beanalyzed as text, with characters, strings, or other text featuresserving to identify content zones or elements. As an example, a headerelement may be identified in a webpage's underlying HTML code byapplication of NLP techniques, where the applied NLP techniques mayinclude identifying a given zone where a first detected string reads“<ZONE>” and a second detected string reads</ZONE>.” In the example,“ZONE” is provided as an example string which may be substituted forother, relevant strings in NLP analysis.

At S330, content elements and zones are classified using a trainedmodel. Content elements and zones may be classified using a trainedmodel where the content elements and zones identified at S320 may beused as the inputs for such a model. A trained model may be configuredto correlate the identified content elements and zones with one or morecontent element or zone labels based on a set of classification rulesdeveloped during training. The training of a model for classification ofcontent elements and zones is described in detail with respect to FIG. 4, below.

At S340, classified content elements and zones are returned. Classifiedcontent elements and zones may include the individual content elementsand zones identified at S320, coupled with the content element and zonelabels developed during classification at S330. Classified contentelements and zones may be returned as labeled HTML code, labeled DOMs,in other, like, formats, and any combination thereof. Labeled HTML codemay be the webpage's underlying HTML code, including code features,comment strings, or other, like, features describing the labels of eachzone or element on a per-zone or per-element basis, with respect to theappropriate zones and elements in the underlying HTML code. Further,classified content elements and zones may be returned as labeled DOMs,including labels corresponding to the various “nodes,” as depictedvisually with respect to FIG. 5B, below.

FIG. 4 is an example flowchart 400 describing a method for training asystem for automatic detection of webpage zones of interest, accordingto an embodiment.

At S410, one or more training datasets are collected. Training datasetsmay include one or more webpages, HTML code sets, DOMs, other, like,data, and any combination thereof. The contents of the one or moretraining datasets may include a variety of content zones, elements, andother content types, which be pre-labeled, partially-pre-labeled, orunlabeled. The training datasets can be collected from the database,150, of FIG. 1 , above.

At S420, content elements and zones are labeled. Zones may be labeled atS420 based on one or more the specifications of label categories, labelsub-categories, and the like. Labeling content elements and zones atS420 may further include appending labels to the appropriate sections ofthe webpage's underlying HTML code, to the appropriate “nodes” of thewebpage's unlabeled DOM, as described with respect to FIG. 5A, below, orboth.

At S430, a machine learning model is trained. It may be noted that,while a machine learning model is included in the flowchart 400, one ormore similar or identical models may be included without loss ofgenerality or departure from the scope. Models similar or identical tomachine learning models may include, without limitation, neuralnetworks, deep learning systems, unsupervised machine learning systems,and any combination thereof. The machine learning model may be trainedby analysis of the content element and zone labels applied at S420 andthe correspondence of such labels with the contents of the HTML codefrom which the webpages included in the training dataset arise. The HTMLcode of the webpages included in the training dataset may be analyzedusing natural language processing (NLP) techniques, as well as other,like, techniques, to isolate characters, strings, and other textfeatures corresponding to the labels applied at S420.

Machine learning model training at S430 may include the development ofone or more rules defining correspondences between the labels applied atS420 and the identified characters, strings, and other text features,identified using NLP and other techniques. Where a pattern ofcorrelation between a given text feature and a given applied label isdetected, machine learning model training at S430 may include generatingone or more rules based on the detected correlation. In the applicationof a machine learning model, as trained at S430, such rules may beapplied to label a given content element or zone based on the contentsof the underlying HTML code.

Machine learning model training at S430 may further include thedevelopment of one or more rules defining correspondences betweenlabeled objects within a webpage DOM, such as the labeled nodes of FIG.5B, below. Where a pattern of correlation between the zones or elementsrepresented by specific “nodes” in a DOM and the labels applied to thesame DOM “nodes” is detected, machine learning training S430 may includegenerating one or more rules based on the detected correlation. Inapplication of a machine learning model trained at S430, such rules maybe applied to label a given content element or zone based on thecontents of the webpage DOM.

Further, training at S430 may include training, as describedhereinabove, using a dataset, such as a dataset labeled at S420, or anyportion thereof. Where less than a complete dataset, such as a portionof a dataset, is used during training, the portion of the dataset notused during training may be retained, archived, or otherwise preservedto validate the trained model, such as during testing at S440. In anembodiment, a portion of a dataset may include a specified fraction of adataset, such as, as an example and without limitation, 80%. Where aportion of a dataset includes a specified fraction, the remainingportion of the dataset may be retained as described hereinabove.

At S440, the machine learning model trained at S430 is tested. Themachine learning model may be tested at S440 by analysis of one or morewebpages according to the rules developed during training at S430.During testing at S440, the machine learning model trained at S430 maybe configured to apply one or more labels to content elements or zonesof the webpage or webpages included in the dataset, providing one ormore labeled webpages for subsequent manual review.

Where training at S430 includes training based on a portion of adataset, as described hereinabove, testing at S440 may include testingbased on the portion or portions of the same dataset not used duringtraining at S430. Where testing at S440 includes testing based on theportion or portions of the dataset not used during training at S430,testing at S440 may include testing the trained model against theportion or portions not used during training at S430 and comparing theresults of such testing with the labels applied to the same portion orportions at S420.

At S450, it is determined whether the results of the testing at S440 aresatisfactory. During determination at S450, feedback from, for example,a user, administrator, or other reviewer may be collected to determinewhether the labels applied during testing at S440 correspond with thecontents of the webpage labeled during testing. Further, determinationat S450 may include comparison of one or more training datasets, labeledduring testing at S440 as described hereinabove, with the same datasetor datasets, as labeled manually during training at S420. Duringdetermination at S450, one or more labeled content elements or zones maybe reviewed. Where all content elements or zones are correctly labeled,or where a percentage or number of correct labels exceeds apredetermined threshold, execution of the training method terminates.Where the number of incorrect labels exceeds a predefined threshold,requiring revision of the machine learning model, execution of thetraining process continues at S455.

At S455, unsatisfactory labels are marked. Marking unsatisfactory labelsmay include specifying one or more content elements to which incorrectlabels are applied. Where unsatisfactory labels are marked at S455,rules corresponding to the unsatisfactory label or labels, such as thoserules generated during training at S430, may be flagged, eitherautomatically or manually, and included in retraining input provided inthe continuation of the training process at S430. Where allunsatisfactory labels are marked, and the corresponding rules areflagged, the marked labels and flagged rules are returned as inputs intothe execution of the machine learning model training step at S430,providing for revision of the machine learning model based on theflagged unsatisfactory rules.

FIG. 5A is a diagram depicting an unlabeled document object model (DOM)tree 500, according to an embodiment. The unlabeled DOM tree 500provides a visual representation of the hierarchical structure of awebpage's HTML code, with content zones or elements represented asnodes, 510-1 through 510-6 (hereinafter, “nodes” 510). In the exampleunlabeled DOM tree 500, related nodes 510 are joined by “links” 520,representing the relationships between two nodes 410. In the exampleunlabeled DOM tree 500, links 520 are established between nodes 510-1and 510-2 and between nodes 510-3 and 510-1. In the example unlabeledDOM tree 500, nodes 510-3 and 510-2 are disposed on a second tier belowthe first tier occupied by node 510-1, reflecting a structure whereinthe content element or zone represented by node 510-1 includes thecontent elements or zones represented by nodes 510-2 and 510-3. Althoughonly the link 520 between nodes 510-1 and 510-2 is labeled, this labelis provided for simplicity, and other, like, links 520 may be likewiselabeled without loss of generality or departure from the scope of thedisclosure.

FIG. 5B is a diagram depicting a labeled document object model (DOM)tree 530, according to an embodiment. The labeled DOM tree 530 includesa plurality of nodes, labeled as “others,” 540-1 through 540-4(hereinafter, “other nodes” 540), “cart” 550, and “menu” 560, joined by“links” 520 representing relationships between the various nodes. Thevarious nodes, 540, 550, and 560, may be labeled nodes of an unlabeledDOM tree, such as the unlabeled DOM tree, 500, of FIG. 5A, above. Nodesmay be labeled according to methods similar or identical to thosedescribed hereinabove, and “other” nodes 540 may be so labeled where thelabeling method or methods applied do not provide for labeling of thecontent zone or element types represented by the respective “other”nodes 540. Similarly, nodes such as “cart” 550 and “menu” 560 may be solabeled according to the content zone or element types represented bythe various nodes. Although only the link 520 between nodes 540-1 and550 is labeled, this label is provided for simplicity, and other, like,links 520 may be likewise labeled without loss of generality ordeparture from the scope of the disclosure.

FIG. 6 is an example page and zone categorization table 600, accordingto an embodiment. The page and zone categorization table 600 includes aplurality of categories, 610-1 through 610-N (hereinafter, “category”610 and “categories” 610), with each category 610 including a pluralityof sub-categories, such as those included in the example table 600 assub-categories 620-1 through 620-M (hereinafter, “sub-category” 620 and“sub-categories” 620). Categories 610 describe a first level of contentcategorization and organization, while sub-categories 620 describe asecond level of categorization. Sub-categories 620 may be implemented assubsets or “members” of categories 610. In an embodiment, categories 610and sub-categories 620 may be merged to provide a non-hierarchical setof webpage categorization labels.

The categories 610 included in the categorization table 600 includepage, zone, or element types relevant to various aspects of one or morewebpages. Examples of categories 610 include “cart,” relevant to adigital shopping cart in an e-commerce page, and “checkout,” relevant tocompleting a purchase in an e-commerce page. Examples of sub-categories620 include a “delete” sub-category 620 of a “cart” category 610,relevant to elements for deleting an item from a digital shopping cartin an e-commerce page, and a “surname” sub-category 620 of an “accountcreation” category 610, relevant to elements for the entry of ashopper's surname during account creation.

The categorization table 600, and other, like, lists, maps, or othercollections of page or zone categories 610 or sub-categories 620, may begenerated by a variety of means including, without limitation, manualentry and definition, machine learning processes, collection fromvarious sources, such as web servers and databases, other, like, means,and any combination thereof. Where the categorization table 600, andother, like, lists, maps, or other collections of zone or elementcategories 610 or sub-categories 620 may be generated by machinelearning processes, the machine learning processes used may besupervised machine learning processes, unsupervised machine learningprocesses, other, like, processes, and any combination thereof.

Identically-named sub-categories 620 may be included in one or morecategories 610. Where two or more sub-categories 620 with identicalnames are included in different categories 610, the identically-namedsub-categories 620 may include content elements or zones with identicalcontent, similar content, or content which is neither identical norsimilar, but which is relevant to the same sub-category 620. As a firstexample, a “cart” sub-category 620 within a page having an “accountcreation” category 610 may include an element which, when clicked,directs a site visitor to a cart page, and an identical element may beincluded in a “cart” sub-category 620 within a page having a “home”category 610. In a second example, illustrating a case wherein twoidentically-named sub-categories 620 have content which is neithersimilar nor identical, a webpage zone allowing a site visitor to reviewthe contents of their digital cart during checkout may fall within a“cart” sub-category 620 of a page having a “checkout” category 610,despite the webpage zone not including the same clickable elementcapable of redirecting the site visitor to a cart page, as described inthe first example.

In an embodiment, pages and zones may be categorized or sub-categorizedas “others” where the same pages and zones do not match predefinedcategories 610 or sub-categories 620, such as those included in thecategorization table 600. As an example, a categorization table 600,including predefined categories 610 and sub-categories 620, includescategories 610 for “account,” “menu,” and “cart” zones. In the sameexample, where a given webpage includes ten individual zones, with onematching “account,” two matching “menu,” and two matching “cart,” theremaining five zones are categorized as “others.”

Sub-categories 620 and categories 610 may be applicable to webpageelements, webpage zones, individual webpages, and clusters of webpages.In an example, and without limitation, a webpage relevant to a “cart”category 610 may include multiple content zones, one of which may berelevant to a “menu” sub-category 620.

FIG. 7A is an illustration depicting a webpage 700 prior to zoneidentification, according to an embodiment. The webpage 700 depictedincludes a plurality of content zones, 710-1 through 710-5 (hereinafter,“content zones” 710). The webpage 700 shown in the illustration providesan example of a checkout page for a shopping website and includesvarious elements found therein including, without limitation, a menubutton 710-1, a search bar 710-2, a cart button 710-3, a quantity field710-4, and a product image 710-5, among others. In the illustration, thewebpage 700 includes content zones 710 which have not been detected oridentified by content zone detection methods, such as those depictedhereinabove.

FIG. 7B is an illustration depicting a webpage 700 following zoneidentification, according to an embodiment. The webpage 700 depicted inthe illustration includes a plurality of identified content zones, 720-1through 720-5 (hereinafter, “identified content zones” 720). Theidentified content zones 720 included in the illustration includeshading reflecting the detection of a content zone. Further, as depictedwith respect to the “product image” label 725, one or more identifiedcontent zones 720 may include labels 725 reflecting the contents of therespective content zones. Although only a “product image” label 725 isincluded in FIG. 7B for sake of simplicity, it may be understood thatadditional labels 725 may be included in the various identified contentzones 720 without loss of generality or departure from the scope of thedisclosure. Identified content zones 720 may be identified according tothe methods described hereinabove.

FIG. 7C is an illustration depicting a webpage 700 following zoneidentification and including a zone identification confidence score 730,according to an embodiment. The webpage 700 depicted in the illustrationincludes a plurality of identified content zones, 720-1 through 720-5(hereinafter, “identified content zones” 720). The identified contentzones 720 included in the illustration include shading reflecting thedetection of a content zone. Identified content zones 720 may beidentified according to the methods described hereinabove. Further, thewebpage 700 depicted in the illustration includes an example of a zoneidentification confidence score 730. The zone identification confidencescore 730 reflects the confidence that a given identified contentelement or zone 720 matches the category or label attached to theidentified zone 720 during identification. Zone identificationconfidence scores 730 may be determined according to the methodsdescribed hereinabove, and may be applicable to one or more identifiedcontent zones 720 of the same webpage, including the case ofsimultaneous determination and display of zone identification confidencescores 730 for some or all of the identified content zones 720 of awebpage 700.

FIG. 8 is an example schematic diagram of an analytic engine 130,according to an embodiment. The analytic engine 130 includes aprocessing circuitry 810 coupled to a memory 820, a storage 830, and anetwork interface 840. In an embodiment, the components of the engine130 may be communicatively connected via a bus 850.

The processing circuitry 810 may be realized as one or more hardwarelogic components and circuits. For example, and without limitation,illustrative types of hardware logic components that can be used includefield programmable gate arrays (FPGAs), application-specific integratedcircuits (ASICs), Application-specific standard products (ASSPs),system-on-a-chip systems (SOCs), graphics processing units (GPUs),tensor processing units (TPUs), general-purpose microprocessors,microcontrollers, digital signal processors (DSPs), and the like, or anyother hardware logic components that can perform calculations or othermanipulations of information.

The memory 820 may be volatile (e.g., random access memory, etc.),non-volatile (e.g., read only memory, flash memory, etc.), or acombination thereof.

In one configuration, software for implementing one or more embodimentsdisclosed herein may be stored in the storage 830. In anotherconfiguration, the memory 820 is configured to store such software.Software shall be construed broadly to mean any type of instructions,whether referred to as software, firmware, middleware, microcode,hardware description language, or otherwise. Instructions may includecode (e.g., in source code format, binary code format, executable codeformat, or any other suitable format of code). The instructions, whenexecuted by the processing circuitry 810, cause the processing circuitry810 to perform the various processes described herein.

The storage 830 may be magnetic storage, optical storage, and the like,and may be realized, for example, as flash memory or other memorytechnology, compact disk-read only memory (CD-ROM), Digital VersatileDisks (DVDs), or any other medium which can be used to store the desiredinformation.

The network interface 840 allows the analytic engine 130 to communicatewith the various components, devices, and systems described herein forautomatic detection of webpage zones of interest, and for other,related, purposes.

It should be understood that the embodiments described herein are notlimited to the specific architecture illustrated in FIG. 8 , and otherarchitectures may be equally used without departing from the scope ofthe disclosed embodiments.

The various embodiments disclosed herein can be implemented as hardware,firmware, software, or any combination thereof. Moreover, the softwareis preferably implemented as an application program tangibly embodied ona program storage unit or computer-readable medium consisting of parts,or of certain devices and/or a combination of devices. The applicationprogram may be uploaded to, and executed by, a machine comprising anysuitable architecture. Preferably, the machine is implemented on acomputer platform having hardware such as one or more central processingunits (“CPUs”), a memory, and input/output interfaces. The computerplatform may also include an operating system and microinstruction code.The various processes and functions described herein may be either partof the microinstruction code or part of the application program, or anycombination thereof, which may be executed by a CPU, whether or not sucha computer or processor is explicitly shown. In addition, various otherperipheral units may be connected to the computer platform such as anadditional data storage unit and a printing unit. Further, anon-transitory computer readable medium is any computer readable mediumexcept for a transitory propagating signal.

All examples and conditional language recited herein are intended forpedagogical purposes to aid the reader in understanding the principlesof the disclosed embodiment and the concepts contributed by the inventorto furthering the art, and are to be construed as being withoutlimitation to such specifically recited examples and conditions.Moreover, all statements herein reciting principles, aspects, andembodiments of the disclosed embodiments, as well as specific examplesthereof, are intended to encompass both structural and functionalequivalents thereof. Additionally, it is intended that such equivalentsinclude both currently known equivalents as well as equivalentsdeveloped in the future, i.e., any elements developed that perform thesame function, regardless of structure.

It should be understood that any reference to an element herein using adesignation such as “first,” “second,” and so forth does not generallylimit the quantity or order of those elements. Rather, thesedesignations are generally used herein as a convenient method ofdistinguishing between two or more elements or instances of an element.Thus, a reference to first and second elements does not mean that onlytwo elements may be employed there or that the first element mustprecede the second element in some manner. Also, unless statedotherwise, a set of elements comprises one or more elements.

As used herein, the phrase “at least one of” followed by a listing ofitems means that any of the listed items can be utilized individually,or any combination of two or more of the listed items can be utilized.For example, if a system is described as including “at least one of A,B, and C,” the system can include A alone; B alone; C alone; 2A; 2B; 2C;3A; A and B in combination; B and C in combination: A and C incombination; A, B, and C in combination; 2A and C in combination; A, 3B,and 2C in combination; and the like.

What is claimed is:
 1. A method comprising: receiving a webpage analysisrequest, wherein the webpage analysis request comprises a webpage in awebsite; identifying at least one zone in the webpage, wherein the atleast one zone is a content element of the webpage; classifying the atleast one zone into a category of interest based on a trained machinelearning model configured to classify document object model (DOM)elements of the webpage, wherein the category of interest is a categorydetermined based on a functionality of the website; and displaying avisual representation of the webpage, the visual representationcomprising at least one zone indicator which includes a shaded highlightover the at least one zone and a zone label.
 2. The method of claim 1,wherein the visual representation further comprises at least one contentidentification score, wherein the at least one content identificationscore is generated based on HTML code of the at least one zone of thewebpage and further based on classification rules developed duringtraining of the machine learning model.
 3. The method of claim 2,wherein the at least one content identification score is a percentagethat reflects a likelihood that the at least one zone matches itsrespective classification.
 4. The method of claim 1, wherein classifyingthe at least one zone into the category of interest further comprises:extracting a DOM for the webpage; identifying content elements and zonesin the DOM; classifying content elements and zones using the trainedmachine learning model; and returning classified content elements andzones.
 5. The method of claim 1, wherein generating the trained machinelearning model further comprises: collecting a training dataset;labeling content elements and zones in the collected training dataset;training the machine learning model; and testing the trained machinelearning model against an unlabeled page.
 6. The method of claim 5,further comprising: evaluating results of the testing of the trainedmachine learning model against an unlabeled page; marking unsatisfactorylabels; and retraining the machine learning model.
 7. The method ofclaim 1, wherein the website is an e-commerce website.
 8. The method ofclaim 1, wherein the category of interest includes a default category,wherein the default category does not designate a specific category ofinterest.
 9. A system comprising: a processor; and a memory storinginstructions that, when executed by the processor, configure theprocessor to perform operations comprising: receiving a webpage analysisrequest, wherein the webpage analysis request comprises a webpage in awebsite; identifying at least one zone in the webpage, wherein the atleast one zone is a content element of the webpage; classifying the atleast one zone into a category of interest based on a trained machinelearning model configured to classify document object model (DOM)elements of the webpage, wherein the category of interest is a categorydetermined based on a functionality of the website; and displaying avisual representation of the webpage, the visual representationcomprising at least one zone indicator which includes a shaded highlightover the at least one zone and a zone label.
 10. The system of claim 9,wherein the visual representation further comprises at least one contentidentification score, wherein the at least one content identificationscore is generated based on HTML code of the at least one zone of thewebpage and further based on classification rules developed duringtraining of the machine learning model.
 11. The system of claim 10,wherein the at least one content identification score is a percentagethat reflects a likelihood that the at least one zone matches itsrespective classification.
 12. The system of claim 9, whereinclassifying the at least one zone into the category of interest furthercomprises: extracting a DOM for the webpage; identifying contentelements and zones in the DOM; classifying content elements and zonesusing the trained machine learning model; and returning classifiedcontent elements and zones.
 13. The system of claim 9, whereingenerating the trained machine learning model further comprises:collecting a training dataset; labeling content elements and zones inthe collected training dataset; training the machine learning model; andtesting the trained machine learning model against an unlabeled page.14. The system of claim 13, the operations further comprising:evaluating results of the testing of the trained machine learning modelagainst an unlabeled page; marking unsatisfactory labels; and retrainingthe machine learning model.
 15. The system of claim 9, wherein thewebsite is an e-commerce website.
 16. The system of claim 9, wherein thecategory of interest includes a default category, wherein the defaultcategory does not designate a specific category of interest.
 17. Anon-transitory computer-readable storage medium, the computer-readablestorage medium including instructions that when executed by a computer,cause the computer to perform operations comprising: receiving a webpageanalysis request, wherein the webpage analysis request comprises awebpage in a website; identifying at least one zone in the webpage,wherein the at least one zone is a content element of the webpage;classifying the at least one zone into a category of interest based on atrained machine learning model configured to classify document objectmodel (DOM) elements of the webpage, wherein the category of interest isa category determined based on a functionality of the website; anddisplaying a visual representation of the webpage, the visualrepresentation comprising at least one zone indicator which includes ashaded highlight over the at least one zone and a zone label.
 18. Thenon-transitory computer-readable storage medium of claim 17, wherein thevisual representation further comprises at least one contentidentification score, wherein the at least one content identificationscore is generated based on HTML code of the at least one zone of thewebpage and further based on classification rules developed duringtraining of the machine learning model.
 19. The non-transitorycomputer-readable storage medium of claim 18, wherein the at least onecontent identification score is a percentage that reflects a likelihoodthat the at least one zone matches its respective classification. 20.The non-transitory computer-readable storage medium of claim 17, whereinclassifying the at least one zone into the category of interest furthercomprises: extracting a DOM for the webpage; identifying contentelements and zones in the DOM; classifying content elements and zonesusing the trained machine learning model; and returning classifiedcontent elements and zones.